PropertyT.jl/GroupAlgebras.jl

module GroupAlgebras

import Base: convert, show, isequal, ==
import Base: +, -, *, //
import Base: size, length, norm

export GroupAlgebraElement


immutable GroupAlgebraElement{T<:Number}
    coordinates::Vector{T}
    product_matrix::Array{Int,2}
    # basis::Array{Any,1}

    function GroupAlgebraElement(coordinates::Vector{T},
        product_matrix::Array{Int,2})

        length(coordinates) == size(product_matrix,1) ||
            throw(ArgumentError("Matrix has to represent products of basis
                                elements"))
        size(product_matrix, 1) == size(product_matrix, 2) ||
            throw(ArgumentError("Product matrix has to be square"))
        # length(coordinates) == length(basis) || throw(ArgumentError("Coordinates must be given in the given basis"))
        # new(coordinates, product_matrix, basis)
        new(coordinates, product_matrix)
    end
end

# GroupAlgebraElement(c,pm,b) = GroupAlgebraElement(c,pm)
GroupAlgebraElement{T}(c::Vector{T},pm) = GroupAlgebraElement{T}(c,pm)

convert{T<:Number}(::Type{T}, X::GroupAlgebraElement) =
    GroupAlgebraElement(convert(Vector{T}, X.coordinates), X.product_matrix)

show{T}(io::IO, X::GroupAlgebraElement{T}) = print(io,
    "Element of Group Algebra over ", T, "\n", X.coordinates)


function isequal{T, S}(X::GroupAlgebraElement{T}, Y::GroupAlgebraElement{S})
    if T != S
        warn("Comparing elements with different coefficients Rings!")
    end
    X.product_matrix == Y.product_matrix || return false
    X.coordinates == Y.coordinates || return false
    return true
end

(==)(X::GroupAlgebraElement, Y::GroupAlgebraElement) = isequal(X,Y)

function add{T<:Number}(X::GroupAlgebraElement{T}, Y::GroupAlgebraElement{T})
    X.product_matrix == Y.product_matrix || throw(ArgumentError(
    "Elements don't seem to belong to the same Group Algebra!"))
    return GroupAlgebraElement(X.coordinates+Y.coordinates, X.product_matrix)
end

function add{T<:Number, S<:Number}(X::GroupAlgebraElement{T},
    Y::GroupAlgebraElement{S})
    warn("Adding elements with different base rings!")
    return GroupAlgebraElement(+(promote(X.coordinates, Y.coordinates)...),
    X.product_matrix)
end

(+)(X::GroupAlgebraElement, Y::GroupAlgebraElement) = add(X,Y)
(-)(X::GroupAlgebraElement) = GroupAlgebraElement(-X.coordinates, X.product_matrix)
(-)(X::GroupAlgebraElement, Y::GroupAlgebraElement) = add(X,-Y)

function group_star_multiplication{T<:Number}(X::GroupAlgebraElement{T},
    Y::GroupAlgebraElement{T})
    X.product_matrix == Y.product_matrix || ArgumentError(
    "Elements don't seem to belong to the same Group Algebra!")

    result = zeros(X.coordinates)
    for (i,x) in enumerate(X.coordinates), (j,y) in enumerate(Y.coordinates)
        if x*y == 0
            nothing
        else
            index = X.product_matrix[i,j]
            if index == 0
                throw(ArgumentError("The product don't seem to belong to the span of basis!"))
            else
                result[index]+= x*y
            end
        end
    end
    return GroupAlgebraElement(result, X.product_matrix)
end

function group_star_multiplication{T<:Number, S<:Number}(
    X::GroupAlgebraElement{T},
    Y::GroupAlgebraElement{S})
    S == T || warn("Multiplying elements with different base rings!")
    return group_star_multiplication(promote(X,Y)...)
end

(*){T<:Number, S<:Number}(X::GroupAlgebraElement{T},
    Y::GroupAlgebraElement{S}) = group_star_multiplication(X,Y);

(*){T<:Number}(a::T, X::GroupAlgebraElement{T}) = GroupAlgebraElement(
    a*X.coordinates, X.product_matrix)

function scalar_multiplication{T<:Number, S<:Number}(a::T,
    X::GroupAlgebraElement{S})
    if  T!=S
        warn("Scalars and coefficients ring are not the same! Trying to promote...")
    end
    return GroupAlgebraElement(a*X.coordinates, X.product_matrix)
end
(*){T<:Number}(a::T,X::GroupAlgebraElement) = scalar_multiplication(a, X)

//{T<:Rational, S<:Rational}(X::GroupAlgebraElement{T}, a::S) =
    GroupAlgebraElement(X.coordinates//a, X.product_matrix)

//{T<:Rational, S<:Integer}(X::GroupAlgebraElement{T}, a::S) =
    X//convert(T,a)

length(X::GroupAlgebraElement) = length(X.coordinates)
size(X::GroupAlgebraElement) = size(X.coordinates)
norm(X::GroupAlgebraElement, p=2) = norm(X.coordinates, p)

end
Initial (working) code 2016-12-19 15:44:52 +01:00			`module GroupAlgebras`

			`import Base: convert, show, isequal, ==`
			`import Base: +, -, *, //`
			`import Base: size, length, norm`

			`export GroupAlgebraElement`


			`immutable GroupAlgebraElement{T<:Number}`
			`coordinates::Vector{T}`
			`product_matrix::Array{Int,2}`
			`# basis::Array{Any,1}`

			`function GroupAlgebraElement(coordinates::Vector{T},`
			`product_matrix::Array{Int,2})`

			`length(coordinates) == size(product_matrix,1) \|\|`
			`throw(ArgumentError("Matrix has to represent products of basis`
			`elements"))`
			`size(product_matrix, 1) == size(product_matrix, 2) \|\|`
			`throw(ArgumentError("Product matrix has to be square"))`
			`# length(coordinates) == length(basis) \|\| throw(ArgumentError("Coordinates must be given in the given basis"))`
			`# new(coordinates, product_matrix, basis)`
			`new(coordinates, product_matrix)`
			`end`
			`end`

			`# GroupAlgebraElement(c,pm,b) = GroupAlgebraElement(c,pm)`
			`GroupAlgebraElement{T}(c::Vector{T},pm) = GroupAlgebraElement{T}(c,pm)`

			`convert{T<:Number}(::Type{T}, X::GroupAlgebraElement) =`
			`GroupAlgebraElement(convert(Vector{T}, X.coordinates), X.product_matrix)`

			`show{T}(io::IO, X::GroupAlgebraElement{T}) = print(io,`
			`"Element of Group Algebra over ", T, "\n", X.coordinates)`


			`function isequal{T, S}(X::GroupAlgebraElement{T}, Y::GroupAlgebraElement{S})`
			`if T != S`
			`warn("Comparing elements with different coefficients Rings!")`
			`end`
			`X.product_matrix == Y.product_matrix \|\| return false`
			`X.coordinates == Y.coordinates \|\| return false`
			`return true`
			`end`

			`(==)(X::GroupAlgebraElement, Y::GroupAlgebraElement) = isequal(X,Y)`

			`function add{T<:Number}(X::GroupAlgebraElement{T}, Y::GroupAlgebraElement{T})`
DomainError -> ArgumentError as the former don't accept message 2016-12-21 09:57:32 +01:00			`X.product_matrix == Y.product_matrix \|\| throw(ArgumentError(`
Initial (working) code 2016-12-19 15:44:52 +01:00			`"Elements don't seem to belong to the same Group Algebra!"))`
			`return GroupAlgebraElement(X.coordinates+Y.coordinates, X.product_matrix)`
			`end`

			`function add{T<:Number, S<:Number}(X::GroupAlgebraElement{T},`
			`Y::GroupAlgebraElement{S})`
			`warn("Adding elements with different base rings!")`
			`return GroupAlgebraElement(+(promote(X.coordinates, Y.coordinates)...),`
			`X.product_matrix)`
			`end`

			`(+)(X::GroupAlgebraElement, Y::GroupAlgebraElement) = add(X,Y)`
			`(-)(X::GroupAlgebraElement) = GroupAlgebraElement(-X.coordinates, X.product_matrix)`
			`(-)(X::GroupAlgebraElement, Y::GroupAlgebraElement) = add(X,-Y)`

			`function group_star_multiplication{T<:Number}(X::GroupAlgebraElement{T},`
			`Y::GroupAlgebraElement{T})`
DomainError -> ArgumentError as the former don't accept message 2016-12-21 09:57:32 +01:00			`X.product_matrix == Y.product_matrix \|\| ArgumentError(`
Initial (working) code 2016-12-19 15:44:52 +01:00			`"Elements don't seem to belong to the same Group Algebra!")`

			`result = zeros(X.coordinates)`
			`for (i,x) in enumerate(X.coordinates), (j,y) in enumerate(Y.coordinates)`
Warn in multiplication of elts of K[G], when discarding a product 2016-12-20 17:57:42 +01:00			`if x*y == 0`
			`nothing`
			`else`
			`index = X.product_matrix[i,j]`
			`if index == 0`
DomainError -> ArgumentError as the former don't accept message 2016-12-21 09:57:32 +01:00			`throw(ArgumentError("The product don't seem to belong to the span of basis!"))`
Warn in multiplication of elts of K[G], when discarding a product 2016-12-20 17:57:42 +01:00			`else`
			`result[index]+= x*y`
			`end`
Initial (working) code 2016-12-19 15:44:52 +01:00			`end`
			`end`
			`return GroupAlgebraElement(result, X.product_matrix)`
			`end`

			`function group_star_multiplication{T<:Number, S<:Number}(`
			`X::GroupAlgebraElement{T},`
			`Y::GroupAlgebraElement{S})`
			`S == T \|\| warn("Multiplying elements with different base rings!")`
			`return group_star_multiplication(promote(X,Y)...)`
			`end`

			`(*){T<:Number, S<:Number}(X::GroupAlgebraElement{T},`
			`Y::GroupAlgebraElement{S}) = group_star_multiplication(X,Y);`

			`(*){T<:Number}(a::T, X::GroupAlgebraElement{T}) = GroupAlgebraElement(`
			`a*X.coordinates, X.product_matrix)`

			`function scalar_multiplication{T<:Number, S<:Number}(a::T,`
			`X::GroupAlgebraElement{S})`
			`if T!=S`
			`warn("Scalars and coefficients ring are not the same! Trying to promote...")`
			`end`
			`return GroupAlgebraElement(a*X.coordinates, X.product_matrix)`
			`end`
			`(*){T<:Number}(a::T,X::GroupAlgebraElement) = scalar_multiplication(a, X)`

			`//{T<:Rational, S<:Rational}(X::GroupAlgebraElement{T}, a::S) =`
			`GroupAlgebraElement(X.coordinates//a, X.product_matrix)`

			`//{T<:Rational, S<:Integer}(X::GroupAlgebraElement{T}, a::S) =`
			`X//convert(T,a)`

			`length(X::GroupAlgebraElement) = length(X.coordinates)`
			`size(X::GroupAlgebraElement) = size(X.coordinates)`
			`norm(X::GroupAlgebraElement, p=2) = norm(X.coordinates, p)`

			`end`